Crack Propagation in the Tibia Bone within Total Knee Replacement Using the eXtended Finite Element Method

Nguyen, Ho-Quang; Nguyen, Trieu-Nhat-Thanh; Pham, Thinh-Quy-Duc; Nguyen, Van Dung; Tran, Xuan Van; Dao, Tien-Tuan

doi:10.3390/app11104435

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Crack Propagation in the Tibia Bone within Total Knee Replacement Using the eXtended Finite Element Method

Nguyen, Ho-Quang; Nguyen, Trieu-Nhat-Thanh; Pham, Thinh-Quy-Duc et al.

2021 • In Applied Sciences, 11 (10)

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https://hdl.handle.net/2268/266499

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10.3390/app11104435

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Keywords :

tibia bone; crack initiation; crack propagation; total knee replacement (TKR); age-related effect; eXtended finite element method (X-FEM)

Abstract :

[en] Understanding of fracture mechanics of the human knee structures within total knee replacement (TKR) allows a better decision support for bone fracture prevention. Numerous studies addressed these complex injuries involving the femur bones but the full macro-crack propagation from crack initiation to final failure and age-related effects on the tibia bone were not extensively studied. The present study aimed to develop a patient-specific model of the human tibia bone and the associated TKR implant, to study fatigue and fracture behaviors under physiological and pathological (i.e., age-related effect) conditions. Computed tomography (CT) data were used to develop a patient-specific computational model of the human tibia bone (cortical and cancellous) and associated implants. First, segmentation and 3D-reconstruction of the geometrical models of the tibia and implant were performed. Then, meshes were generated. The locations of crack initiation were identified using the clinical observation and the fatigue crack initiation model. Then, the propagation of the crack in the bone until final failure was investigated using the eXtended finite element method (X-FEM). Finally, the obtained outcomes were analyzed and evaluated to investigate the age-effects on the crack propagation behaviors of the bone. For fatigue crack initiation analysis, the stress amplitude–life S–N curve witnessed a decrease with increasing age. The maximal stress concentration caused by cyclic loading resulted in the weakening of the tibia bone under TKR. For fatigue crack propagation analysis, regarding simulation with the implant, the stress intensity factor and the energy release rate tended to decrease, as compared to the tibia model without the implant, from 0.15 ÷ 2.5 to 0.11 ÷ 1.9 (MPam−−√) and from 10 ÷ 240 to 5 ÷ 133 (Jm−2), respectively. This led to the drop in crack propagation speed. This study provided, for the first time, a detailed view on the full crack path from crack initiation to final failure of the tibia bone within the TKR implant. The obtained outcomes also suggested that age (i.e., bone strength) also plays an important role in tibia crack and bone fracture. In perspective, patient-specific bone properties and dynamic loadings (e.g., during walking or running) are incorporated to provide objective and quantitative indicators for crack and fracture prevention, during daily activities.

Disciplines :

Mechanical engineering

Author, co-author :

Nguyen, Ho-Quang

Nguyen, Trieu-Nhat-Thanh

Pham, Thinh-Quy-Duc

Nguyen, Van Dung ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Computational & Multiscale Mechanics of Materials (CM3)

Tran, Xuan Van

Dao, Tien-Tuan

Language :

English

Title :

Crack Propagation in the Tibia Bone within Total Knee Replacement Using the eXtended Finite Element Method

Publication date :

13 May 2021

Journal title :

Applied Sciences

eISSN :

2076-3417

Publisher :

MDPI, Basel, Switzerland

Volume :

Issue :

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://doi.org/10.3390/app11104435

Available on ORBi :

since 28 December 2021

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